# ***** GloMoSim Configuration File *****

# Glomosim is COPYRIGHTED software.  It is freely available without fee for
# education, or research, or to non-profit agencies. No cost evaluation
# licenses are available for commercial users. By obtaining copies of this
# and other files that comprise GloMoSim, you, the Licensee, agree to abide
# by the following conditions and understandings with respect to the
# copyrighted software:
#
# 1.Permission to use, copy, and modify this software and its documentation
#   for education, research, and non-profit purposes is hereby granted to
#   Licensee, provided that the copyright notice, the original author's names
#   and unit identification, and this permission notice appear on all such
#   copies, and that no charge be made for such copies. Any entity desiring
#   permission to incorporate this software into commercial products or to use
#   it for commercial purposes should contact: 
#
#   Professor Rajive Bagrodia 
#   University of California, Los Angeles 
#   Department of Computer Science 
#   Box 951596 
#   3532 Boelter Hall 
#   Los Angeles, CA 90095-1596 
#   rajive@cs.ucla.edu
#
# 2.NO REPRESENTATIONS ARE MADE ABOUT THE SUITABILITY OF THE SOFTWARE FOR ANY
#   PURPOSE. IT IS PROVIDED "AS IS" WITHOUT EXPRESS OR IMPLIED WARRANTY.
#
# 3.Neither the software developers, the Parallel Computing Lab, UCLA, or any
#   affiliate of the UC system shall be liable for any damages suffered by
#   Licensee from the use of this software.
#
# $Id: config.in.wired.4,v 1.1 2000/08/02 17:23:22 yjyi Exp $
#
# Anything following a "#" is treated as a comment.
#
###############################################################################
#
# The folowing parameter represents the maximum simulation time. The numberd
# portion can be followed by optional letters to modify the simulation time.
# For example:
#        100NS   - 100 nano-seconds
#        100MS   - 100 milli-seconds
#        100S    - 100 seconds
#        100     - 100 seconds (default case)
#        100M    - 100 minutes
#        100H    - 100 hours
#        100D    - 100 days
#

SIMULATION-TIME     10s

#
# The following is a random number seed used to initialize  part of the seed of
# various randomly generated numbers in the simulation. This can be used to vary
# the seed of the simulation to see the consistency of the results of the
# simulation.
#

SEED                1

#
# The following two parameters stand for the physical terrain in which the nodes
# are being simulated. For example, the following represents an area of size 100
# meters by 100 meters. All range parameters are in terms of meters.
#
# Terrain Area we are simulating.
#

TERRAIN-RANGE-X     1000
TERRAIN-RANGE-Y     1000

#
#The following parameter represents the number of nodes being simulated.
#

NUMBER-OF-NODES     4

#
#
#The following parameter represents the node placement strategy.
#- RANDOM: Nodes are placed randomly within the physical terrain.
#- UNIFORM: Based on the number of nodes in the simulation, the physical
#  terrain is divided into a number of cells. Within each cell, a node is
#  placed randomly.
#- GRID: Node placement starts at (0, 0) and are placed in grid format with
#  each node GRID-UNIT away from its neighbors. The number of nodes has to be
#  square of an integer.
#- FILE: Position of nodes is read from NODE-PLACEMENT-FILE. On each line of
#  the file, the x and y position of a single node is separated by a space.
#

# NODE-PLACEMENT      FILE
# NODE-PLACEMENT-FILE ./nodes.input
# NODE-PLACEMENT      GRID
# GRID-UNIT           30  
# NODE-PLACEMENT      RANDOM
NODE-PLACEMENT      UNIFORM

#
# The following represent parameters for mobility. If MOBILITY is set to NO,
# than there is no movement of nodes in the model. For the RANDOM-DRUNKEN model,
# if a node is currently at position (x, y), it can possibly move to (x-1, y),
# (x+1, y), (x, y-1), and (x, y+1); as long as the new position is within the
# physical terrain. For random waypoint, a node randomly selects a destination
# from the physical terrain. It moves in the direction of the destination in 
# a speed uniformly chosen between MOBILITY-WP-MIN-SPEED and 
# MOBILITY-WP-MAX-SPEED (meter/sec). After it reaches its
# destination, the node stays there for MOBILITY-WP-PAUSE time period.
# The MOBILITY-INTERVAL is used in some models that a node updates its position
# every MOBILITY-INTERVAL time period. The MOBILITY-D-UPDATE is used that a node 
# updates its position based on the distance (in meters).
#

MOBILITY  NONE

# Random Waypoint and its required parameters.

#MOBILITY RANDOM-WAYPOINT
#MOBILITY-WP-PAUSE       30S
#MOBILITY-WP-MIN-SPEED   0
#MOBILITY-WP-MAX-SPEED   10

#MOBILITY TRACE
#MOBILITY-TRACE-FILE ./mobility.in

#MOBILITY PATHLOSS-MATRIX

# The following parameters are necessary for all the mobility models

MOBILITY-POSITION-GRANULARITY 0.5

#####################################################################
#
# PROPAGATION-LIMIT:
#   Signals with powers below PROPAGATION-LIMIT (in dBm)
#   are not delivered. This value must be smaller than
#   RADIO-RX-SENSITIVITY + RADIO-ANTENNA-GAIN of any node
#   in the model. Otherwise, simulation results may be
#   incorrect. Lower value should make the simulation more
#   precise, but it also make the execution time longer.
# 
PROPAGATION-LIMIT      -111.0

#
# PROPAGATION-PATHLOSS: pathloss model
#   FREE-SPACE:
#     Friss free space model.
#     (path loss exponent, sigma) = (2.0, 0.0)
#   TWO-RAY:
#     Two ray model. It uses free space path loss
#     (2.0, 0.0) for near sight and plane earth
#     path loss (4.0, 0.0) for far sight. The antenna
#     height is hard-coded in the model (1.5m).
#   PATHLOSS-MATRIX:
#
#PROPAGATION-PATHLOSS   FREE-SPACE
PROPAGATION-PATHLOSS   TWO-RAY
#PROPAGATION-PATHLOSS   PATHLOSS-MATRIX

#
# NOISE-FIGURE: noise figure
#
NOISE-FIGURE    10.0

#
# TEMPARATURE: temparature of the environment (in K)
#
TEMPARATURE     290.0


#########################################
#
# RADIO-TYPE: radio model to transmit and receive packets
#   RADIO-ACCNOISE: standard radio model
#   RADIO-NONOISE: abstract radio model
#   (RADIO-NONOISE is compatible with the current version (2.1b5)
#    of ns-2 radio model)
#
RADIO-TYPE              RADIO-ACCNOISE
#RADIO-TYPE              RADIO-NONOISE

#
# RADIO-FREQUENCY: frequency (in heltz)  (Identifying variable for multiple
#  radios)
#
RADIO-FREQUENCY     2.4e9

#
# RADIO-BANDWIDTH: bandwidth (in bits per second)
#
RADIO-BANDWIDTH     2000000

#
# RADIO-RX-TYPE: packet reception model
#   SNR-BOUNDED:
#     If the Signal to Noise Ratio (SNR) is more than
#     RADIO-RX-SNR-THRESHOLD (in dB), it receives the signal
#     without error. Otherwise the packet is dropped.
#     RADIO-RX-SNR-THRESHOLD needs to be specified.
#   BER-BASED:
#     It looks up Bit Error Rate (BER) in the SNR - BER table
#     specified by BER-TABLE-FILE.
#
RADIO-RX-TYPE           SNR-BOUNDED
RADIO-RX-SNR-THRESHOLD  10.0
#RADIO-RX-SNR-THRESHOLD  8.49583

#RADIO-RX-TYPE           BER-BASED
#BER-TABLE-FILE          ./ber_bpsk.in

#
# RADIO-TX-POWER: radio transmition power (in dBm)
#
RADIO-TX-POWER        15.0

#
# RADIO-ANTENNA-GAIN: antenna gain (in dB)
#
RADIO-ANTENNA-GAIN  0.0

#
# RADIO-RX-SENSITIVITY: sensitivity of the radio (in dBm)
#
RADIO-RX-SENSITIVITY -91.0

#
# RADIO-RX-THRESHOLD: Minimum power for received packet (in dBm)
#
RADIO-RX-THRESHOLD -81.0

#
##############################
#

#MAC-PROTOCOL        802.11
#MAC-PROTOCOL        CSMA
#MAC-PROTOCOL        MACA

#MAC-PROTOCOL        TSMA
#TSMA-MAX-NODE-DEGREE      8

# for wired network

MAC-PROTOCOL WIRED
WIRED-LINK-FILE     wired_4.conf


#MAC-PROPAGATION-DELAY 1000NS

#
# PROMISCUOUS-MODE defaults to YES and is necessary if nodes want
# to overhear packets destined to the neighboring node. 
# Currently this option needs to be set to YES only for DSR is selected
# as routing protocol.  Setting it to "NO" may save a trivial amount
# of time for other protocols.

#PROMISCUOUS-MODE     NO

##############################
# 
# Currently the only choice.

NETWORK-PROTOCOL    IP
NETWORK-OUTPUT-QUEUE-SIZE-PER-PRIORITY 100

#RED-MIN-QUEUE-THRESHOLD 150
#RED-MAX-QUEUE-THRESHOLD 200
#RED-MAX-MARKING-PROBABILITY 0.1
#RED-QUEUE-WEIGHT .0001
#RED-TYPICAL-PACKET-TRANSMISSION-TIME 64000NS


##############################
#


#ROUTING-PROTOCOL    BELLMANFORD
#ROUTING-PROTOCOL    AODV
#ROUTING-PROTOCOL    DSR
#ROUTING-PROTOCOL    LAR1
#ROUTING-PROTOCOL    WRP
#ROUTING-PROTOCOL    FISHEYE

#ROUTING-PROTOCOL    ZRP
#ZONE-RADIUS         2

ROUTING-PROTOCOL    STATIC
STATIC-ROUTE-FILE   rtable_4.in


#
# The following is used to setup applications such as FTP and Telnet.
# The file will need to contain parameters that will be use to
# determine connections and other characteristics of the particular 
# application.
#


APP-CONFIG-FILE   ./app_wired_4.conf


#
# The following parameters determine if you are interested in the statistics of
# a a single or multiple layer. By specifying the following parameters as YES,
# the simulation will provide you with statistics for that particular layer. All
# the statistics are compiled together into a file called "GLOMO.STAT" that is
# produced at the end of the simulation. If you need the statistics for a
# particular node or particular protocol, it is easy to do the filtering. Every
# single line in the file is of the following format:
# Node:      9, Layer:  RadioNoCapture, Total number of collisions is 0
#

APPLICATION-STATISTICS          YES
TCP-STATISTICS                  NO
UDP-STATISTICS                  YES
ROUTING-STATISTICS              NO
NETWORK-LAYER-STATISTICS        NO
MAC-LAYER-STATISTICS            YES
RADIO-LAYER-STATISTICS          NO
CHANNEL-LAYER-STATISTICS        NO 
MOBILITY-STATISTICS             NO 

#
#
# GUI-OPTION: YES allows GloMoSim to communicate with the Java Gui Vis Tool 
#             NO does not

GUI-OPTION   NO
GUI-RADIO    NO
GUI-ROUTING  NO


